|Publication number||US4483630 A|
|Application number||US 06/385,294|
|Publication date||Nov 20, 1984|
|Filing date||Jun 4, 1982|
|Priority date||Jun 4, 1982|
|Publication number||06385294, 385294, US 4483630 A, US 4483630A, US-A-4483630, US4483630 A, US4483630A|
|Inventors||David W. Varela|
|Original Assignee||Thomas M. Kerley|
|Export Citation||BiBTeX, EndNote, RefMan|
|Patent Citations (8), Non-Patent Citations (1), Referenced by (29), Classifications (6), Legal Events (7)|
|External Links: USPTO, USPTO Assignment, Espacenet|
Ultrasonic thermometers for measuring high temperatures and temperature profiles are known in the art and have become more important with increased research at high temperatures. These ultrasonic thermometers operate by sensing changes in the velocity of reflected sound waves propagated through a sensor in contact with the object for which the temperature is desired to be known.
Generally, ultrasonic thermometers consist of an electromagnetic coil surrounded magnetostrictive iron-cobalt head welded to a thoriated tungsten wire which comprises the means by which the heat is sensed. At the tip of the thoriated tungsten wire heat sensor are small notches or discontinuities formed at regular intervals. The portion of the thoriated tungsten wire sensor in contact with the matter which temperature is to be measured is usually contained in a protective tungsten sheath.
The electromagnetic coil surrounding a portion of the magnetostrictive iron-cobalt head is pulsed with an electrical pulse generating a pulsed magnetic field which produces acoustic or sound pulses in the magnetostrictive head. These sound pulses are propagated through the magnetostrictive head to the thoriated tungsten wire sensor which continues the acoustic pulse along the wire sensor to the area of the notches. Each time it passes a pair of formed notches or discontinuities in the wire sensor, a reflection of part of that acoustic pulse is sent back to the magnetostrictive head. Such procedures continue with each notch until the sound pulse reaches the end or tip of the sensor at which time it is returned back to the magnetostrictive iron-cobalt head.
As the pulses from each pair of notches return to the magnetostrictive head, it is sensed by the electromagnetic coil, such signals then amplified and sent on to a signal-processing console for conversion to temperature data. Since the velocity of the reflected pulses between adjacent notches is dependent upon the temperature of the thoriated tungsten wire sensor between the notches, the time between reflected pulses can be translated into an average temperature between adjacent notches.
Problems however have existed in these ultrasonic thermometers due to factors such as maintaining accuracy of the temperature measurements over extended periods of time between different tests and where the equipment may be subject to handling by technicians. It is usual that long and involved calibrating procedures are necessary between tests because of the dependence of the readings upon mechanical factors in the construction and maintenance of the thermometer leading to errors induced by repeated handling by technicians.
Misalignment of the elements of the ultrasonic thermometers in small amounts can easily result in sensed temperature variation errors of ±50° C. Similarily, errors in observed temperatures can occur when the fixture itself holding the elongated wire sensor relative to the pulsing element interferes with the propagation of the ultrasonic signals.
In addition, it has been observed that improper coupling of the elements of prior art ultrasonic thermometers make vast changes in the sensed temperatures for repeated tests leading to inaccuracies in test results.
Another problem area the solution of which has eluded investigators in the past is how to deal with tip reflection, i.e., signal reflection at the end of the elongated wire sensor, since the variation of magnitude of the tip reflection due to coupling and other factors is relatively large in comparison with the other reflected signals. In fact, the general conclusion is that information from end reflection is useless because of the difficulties encountered in trying to reproduce coupling conditions from test to test.
It is to the solution of these problems which the improved invention is directed in order to facilitate accurate and repeatable results not affected by technicians handling or variances in element fabrication and coupling.
The present invention provides an improved ultrasonic thermometer of the pulse-echo type in which high frequency sound waves propagate through a thin wire sensor to be reflected in part from notches or discontinuities in the sensor. By this technique, the differences in arrival time of the reflected sound waves from two adjacent discontinuities is monitored. Knowing the distance between the discontinuities and monitoring the different arrival times is indicative of the average temperature in the section of the sensor between the discontinuities, and temperature profiles along the sensor can be measured with a single wire sensor by placing multiple notches or discontinuities at measured distances along the wire sensor.
The accuracy, reliability, versatility, and repeatability of sensed temperatures in the wire sensor is obtained through the Applicant's improvements in such areas of construction including rigid constraint and alignment of the magnetostrictive head and sensor wire to the pulsing and receiving elements so that the pulsed and reflected acoustic signals are minimally distorted to reduce possible errors in the sensed temperatures.
More particularily, an annular or circumferential groove is cut into the wire sensor proximate its attachment to the magnetostrictive head. A break apart graphite sheath type lock with an annular inward protruding holding ring grips the annular groove of the sensor wire in a securing configuration. The graphite sheath lock is then held in a sensor line holder by graphite set screws engaging the halves of the graphite sheath lock.
Other improvements to Applicant's device are the means by which Applicant couples the electromagnetic pulsing and receiving coil to the magnetostrictive rod or head attached to the sensor line. In this respect, Applicant fabricates a bobbin for containing the coil turns of the electromagnetic coil, which bobbin is held in a bobbin holder. The bobbin holder in turn is connected to the sensor line holder by means of adjustable rod lengths.
Additional improvements by the Applicant to prior art ultrasonic thermometers include placing the annular groove by which the wire sensor is held by the graphite sheath proximate the attachment of the wire sensor to the magnetostrictive iron-cobalt head. In this manner the reflected sound wave of the discontinuity formed by the welded connection of the iron-cobalt magnetostrictive head to the thoriated tungsten wire sensor is swamped by the annular groove formed proximately thereto and does not allow creation of spurious signals which heretofore would cause unreliable readings.
In addition, Applicant's device, by the adjustment of the electromagnetic coil on the magnetostrictive iron-cobalt head provides opportunity for constructive addition of the large reflected wave returning from the end of the head not connected to the thoriated wire sensor to the acoustic pulse transmitted.
Through the accomplishment of precisely aligned pulsating components, i.e., the electromagnetic coil, and the fixed relationship of the elements in the device give repeatable accurate measurements made by the subject ultrasonic thermometer.
Accordingly, it is therefore an object of the subject invention to provide an ultrasonic thermometer which maintains its accuracy over periods of time.
Another object of the subject invention is to provide an ultrasonic thermometer which obviates inaccuracies due to discontinuities presented by connections between the elements of the device.
A still further objective of the subject invention is to provide an ultrasonic thermometer which constructively adds the heretofore undesirable reflection from the magnetostrictive head.
Other objects of the invention will in part be obvious and will in part appear hereinafter. The invention accordingly comprises the apparatus possessing the construction, combination of elements, and arrangement of parts which are exemplied in the following detailed disclosure, and the scope of the application of which will be indicated in the claims.
For further understanding of the nature and objects of the present invention, reference should be made to the following detailed description taken in connection with accompanying drawings wherein:
FIG. 1 is a schematic block diagram of an ultrasonic thermometer system.
FIG. 2 is an enlarged cross-sectional view of the fixture for rigidly holding, aligning, and adjusting the sensor line and pulsing components.
FIG. 3 is a cross-sectional view of a typical application of Applicant's device.
In the various views, like index numbers refer to like elements.
Referring now to FIG. 1, a schematic block diagram of Applicant's ultrasonic thermometer system is detailed. In the lower left hand portion of FIG. 1 is the electromagnetic pulse coil driver 53 which originates the electrical pulse at a selected magnitude, width, and rate, which in turn is applied to the electromagnetic coil 51 surrounding the magnetostrictive head 20, commonly an alloy of 48% cobalt, 47.6% iron, 4% vanadium, and 0.4 manganese. Connected at one end of the rod-like magnetostrictive head 20 is elongated wire sensor 10 having at selected places thereon, a plurality of discontinuities or notches 12 which have been formed or cut into the wire sensor. In many applications, wire sensor 10 is a thoriated tungsten alloy material. Connection of the elongated wire sensor 10 to the magnetostrictive head 20 is accomplished in most cases by welding. Noted proximate to the wire sensor 10 and magnetostrictive head 20 joinder is an additional notch 14 which characterizes one of the features of Applicant's invention. Attached to the electrical wires connecting coil driver 53 to electromagnetic coil 51 is signal processor 60.
Operation of the ultrasonic thermometer is as follows. Coil driver 53 generates the electric pulse which is electrically conducted to electromagnetic coil 51 producing in electromagnetic coil 51 a pulsed electromagnetic field surrounding magnetostrictive coil 20. This pulsed electromagnetic field produces in magnetostrictive head 20 a change of lengthing which in turn produces an acoustic pulse in head 20, which acoustic pulse travels away from the location of electromagnetic coil 51 in both directions along the magnetostrictive head 20. At the free end of magnetostrictive head 20, the acoustic wave is reflected which must be accounted for as later discussed. At the opposite end of magnetostrictive head 20 the acoustic pulse is transferred to the elongated wire sensor 10, traveling to its end thereof where it too is reflected. In both cases, it is realized that the acoustic wave is attenuated as it travels throughout both the magnetostrictive head 20 and elongated wire sensor 10 so that the reflected waves are of lesser magnitude than the original produced waves. In addition, at each discontinuity in the elongated wire sensor 10, a portion of the acoustic wave transmitted along the elements is reflected in the direction opposite. In the drawing shown in FIG. 1, in addition to the acoustic wave being reflected from the free end of megnetostrictive head 20, a reflection will occur at the place of joinder of elongated wire sensor 10 to magnetostrictive head 20, as well as at each discontinuity or notch 12 formed in elongated wire sensor 10.
The function of processor/computer 60 is to sense when the electromagnetic pulse has formed the acoustic pulse, and to sense each reflective acoustic pulse returned by each of the discontinuities in both elements, i.e., magnetostrictive head 20 and elongated sensor 10.
The reflected acoustic pulses travel from each of the discontinuities back to the magnetostrictive head 20 where they induce in electromagnetic coil 51 an electrical pulse which is sensed by the processor 60.
Since it is known that sound or acoustic waves travel at velocities directly dependent upon temperature in the wire sensor 10, it is obvious that knowing the distance between discontinuities in wire sensor 10, and measuring the difference in time of reflected acoustic pulses from adjacent discontinuities, the average temperature of the elongated wire sensor 10 between the discontinuities can be directly determined, and thus a temperature profile of the elongated wire sensor 10 may be determined. If the elongated wire sensor 10 is in contact with materials or objects whose temperature is to be obtained, the output of the processor then will indicate the time between adjacent pulses which is indicative of the average temperatures between adjacent discontinuities.
Processors/computers which include timers/counters measure and display the elapsed time between reflected acoustic pulses, and convert each time to temperature, are commonly known in the field and readily available. It is noted that if desired, an oscilloscope input may be placed across electromagnetic coil 51, and in which case by appropriate horizontal time scale, each of the reflected acoustic pulses may be observed and the time interval therebetween measured.
Referring now to FIG. 2, an enlarged cross-sectional view of the acoustic pulse generating and pulse sensing means fixture for rigidly holding, aligning, and precisely adjusting the electromagnetic coil for operation is detailed. Beginning at the right hand side of FIG. 2, elongated wire sensor 10 is shown in partial section emerging from sensor line holder 31 which, in the preferred embodiment is constructed of aluminum. Sensor line holder 31 is of cylindrical construction having a closed off end with an opening therethrough to pass elongated wire sensor 10. Protruding from opposite sides through threaded openings in sensor line holder 31 are graphite set screws 33 which are adapted to engage the sides of an inner cup-like graphite lock 35 which also, in the preferred embodiment, has an opening through its closed end for engaging notch 14 formed proximate the connection of elongated wire sensor 10 to magnetostrictive head 20. Graphite lock 35 is separatable into two halves which come together around primarily magnetostrictive head 20 and the connection between elongated wire sensor 10 and magnetostrictive head 20. A protruding inward directed annular ring in the opening formed by cup-like graphite lock 35 is adapted to engage notch 14 of the elongated wire sensor 10 in order to hold in a secure configuration the wire sensor 10.
It is noted that the notch of circumferential groove 14 formed in elongated wire sensor 10 is formed very close to the butt weld joining sensor 10 and magnetostrictive head 20. It has been determined that because of the large discontinuity at this joinder, even to reflecting reflected acoustic waves, in order to reduce parasitic reflection oscillations between the joinder and notch 14, notch 14 is located, in the preferred embodiment, approximately 1 mm from the weld. By such method, in addition to reduction of parasitic reflections, reflections from each discontinuity are merged into one return reflection.
While inner cup-like graphite lock 35 has been shown, for ease of illustration, to have an outer diameter considerably less than the inner diameter of sensor line holder 31, it should be understood that in the preferred embodiment it is anticipated that there shall be minimal space between the outside circumferential surface of graphite lock 35 and the inner cylindrical surface of sensor line holder 31. When the device of FIG. 2 is assembled, graphite lock 35 slides into place interior to sensor line holder 31 and graphite set screws 33 protrude only slightly into the cavity of sensor line holder 31 before engaging graphite lock 35.
In addition, in the preferred embodiment, graphite is the preferred material constructing lock 35 since graphite is a material which can be made hard and has a high acoustic mismatch with the elongated wire sensor 10 such as to minimize interference of the propagation of the primary acoustic pulse and its reflected acoustic pulses.
Shown also in FIG. 2 at the intersection of elongated wire sensor 10 and magnetostrictive head 20 is the weld fillet by which the two elements are joined. The primary holding mechanism between graphite lock 35 and the ultrasonic thermometer is the engagement of notch 14 by the inward directed annular ring of graphite lock 35, although in FIG. 2, magnetostrictive head 20 is shown abutting the interior wall of graphite lock 35. It is obvious that since graphite set screws 33 engage the side of graphite lock 35, the orientation with respect to the halves of graphite locks 35 is to make the halve separation at a 90° angle to the engagement by the graphite set screws 33. This is easily accomplished during assembly.
Continuing in FIG. 2, extension rods 37, in the preferred embodiment constructed of aluminum, engage blind threaded holes formed in an axial direction in the cylindrical walls of sensor line holder 31, although, if it is desired, these threaded holes may be completely drilled out through the wall of sensor line holder 31 to emerge from the opposite side, and extension rods 37, being threaded, are held by nuts on both sides of sensor line holder 31.
For simplicity, in FIG. 2 shown in partial section are the aluminum rods 37 and magnetostrictive head 20, the opposite ends of which are connected and surrounded by bobbin holder 39 respectively, which, in the preferred embodiment, is also constructed of aluminum, Bobbin holder 39 comprises a substantially solid cylinder having through its center in its axial direction an opening for magnetostrictive head 20 to pass therethrough, and two openings on either side of magnetostrictive head 20 to receive aluminum rods 37 which, in the area proximate bobbin holder 39, are threaded to receive a pair of threaded nuts 38 and 40. Attached to the end face of bobbin holder 39 is bobbin 41, bobbin 41 in the preferred embodiment is constructed of alumina (aluminum oxide), with the flat circular side of bobbin 41 attached to the flat circular side of bobbin holder 39 by an adhesive. Bobbin 41 is spool-shaped, containing in its annular cavity electromagnetic coil 51. Electromagnetic coil 51 in the preferred embodiment, comprises 124 turns of No. 44 insulated copper wire.
As is obvious in viewing FIG. 2, in assembling the fixture shown in FIG. 2, the graphite lock 35 halves are placed around magnetostrictive head 20 such that the inwardly protruding annular ring in the opening of graphite lock 35 engages the annular groove 14 of the elongated wire sensor 10. When that is accomplished and the halves of graphite lock 35 engaged, elongated wire sensor 10 is slid through the opening in sensor line holder 31 until the graphite lock 35 bottons in the cavity of sensor line holder 31, at which time set screws 33 are screwed in to engage the cylindrical side of graphite lock 35. Extension rods 37 are then screwed into sensor line holder 31 until they bottom, and then nuts 38 screwed onto extension rods 37 to a bottoming position. The bobbin holder 39 is inserted in place over magnetostrictive head 20 and the twin extension rods 37, and nuts 40 put in place. Final adjustment of bobbin holder 39 in place is accomplished with all the system attached and working since the placement of the bobbin holder 39 in relationship to magnetostrictive head 20 in order to null out unwanted reflections is accomplished with the equipment working.
With respect to the earlier mentioned reflection of the acoustic pulse from the free end of magnetostrictive head 20, as well as minimizing reflection from the joinder of magnetostrictive head 20 and elongated wire sensor 10, the bobbin holder 39 having attached bobbin 41 is adjusted by means of nuts 38 and 40 on aluminum rods 37 while observing the electrical pulse sent through electromagnetic coil 51 and the reflected pulse from the free end of magnetostrictive head 20. This reflective pulse, which will be the first in line of reflected pulse because the free end of magnetostrictive head 20 is the closest discontinuity to the place of the originating pulse, will either be additive or subtractive to the original acoustic pulse depending upon the time relationship of the return pulse to the pulse just generated. Since it is anticipated that bobbin 41 will be proximate the free end of magnetostrictive head 20, the time for the beginning edge of the acoustic pulse to travel to the free end of magnetostrictive head 20 and back is very short, it will join the acoustic pulse still being produced and reinforce it, or join the end of it to give a longer continuous pulse.
However, if through misadjustment of the bobbin holder 39, the acoustic pulse from the free end of magnetostrictive head 20 follows the primary acoustic pulse by any sizable time down the wire sensor 10, interference with reflected pulses will be caused as well as the generation of ghost images, all to contribute to gross inaccuracies, false readings, and considerable electrical noise observed on the sensed reflected pulses on the electrical leads of electromagnetic coil 51.
With respect to the signal processing/computing unit 60 containing timers/counters shown in FIG. 1, the operation of which has already been described, such units are well within the state of the art and are commercially available, such as the John Fluke Manufacturing Company, Universal Counter/Timer, Model 7261A, and Hewlett Packard Mini computer, Model 9845. Such processors/computers display the elasped time between reflected pulses, or with the application of known algorithms, will display sensed average temperature between adjacent discontinuities.
Referring now to FIG. 3, Applicant's device is shown in a typical setting for measuring temperatures and temperature profiles interior to an elevated temperature furnace. Shown in greatly exaggerated cross-section is the protective means that surrounds the invention during times of temperature measurement, for example, sheath 61 penetrates to the interior of furnace 60 from the outside environment through an opening in furnace 60. The sheath 61 is sealed at the opening through sealing means 63 which prevent the environment in furnace 60 from leaking out. In open communication with the interior of sheath 60 is housing 65, housing 65 adapted to receive sensor line holder 31 and bobbin holder 39 (here represented by block 35) together with their attachments, while elongated wire sensor 10 resides interiorly to sheath 61. It is very common to place ultrasonic thermometers, or the elongated wire sensors, or both, in an inert atmosphere. This is especially true if the type of metal utilized in the elongated wire sensor is reactive to the components of air at elevated temperatures. Thoriated tungsten is known to oxidize at elevated temperatures and therefore this type of arrangement is suggested for this application.
When it is necessary to place the elongated wire sensor and/or the remaining portion of the invention in an inert atmosphere, the open end of housing 65 is sealed with the ultrasonic thermometer inside residing in an inert environment, and the electrical leads are brought out through the housing 65 with insulated stand-offs. The operation of the ultrasonic thermometer then is accomplished to connection to these electrical leads.
It is realized of course that while the Applicant has suggested materials to be used for the magnetostrictive head 20, the elongated wire sensor 10, and the graphite lock 35, it is known in the art that there are many materials which have similar properties as the magnetostrictive head, the elongated wire sensor, and the graphite lock, and these materials may be utilized as well as Applicant's suggested materials. There is no intent by Applicant to limit the invention to the type of materials suggested.
While a preferred embodiment of Applicant's device has been shown and described, it will be appreciated that there is no intent to limit the invention by such disclosure, but rather it is intended to cover all modifications and alternate embodiments falling within the spirit and the scope of the invention as defined in the appended claims.
|Cited Patent||Filing date||Publication date||Applicant||Title|
|US3216970 *||Apr 30, 1958||Nov 9, 1965||Gevaert Photo Prod Nv||Production of linear aromatic polyesters containing isophthalic acid|
|US3514747 *||Oct 25, 1968||May 26, 1970||Panametrics||Ultrasonic sensing system|
|US3540265 *||May 21, 1968||Nov 17, 1970||Panametrics||Dual ultrasonic sensors employing differing modes of ultrasonic transmission|
|US3580076 *||Jun 28, 1967||May 25, 1971||Atomic Energy Authority Uk||Acoustic thermometers|
|US3633423 *||Jan 28, 1970||Jan 11, 1972||Bell John F W||Acoustic thermometers|
|US3717033 *||May 15, 1970||Feb 20, 1973||Gordon Eng Co||Ultrasonic apparatus, particularly for thermometry|
|US4020692 *||Sep 26, 1975||May 3, 1977||The United States Of America As Represented By The United States Energy Research And Development Administration||Ultrasonic thermometer isolation standoffs|
|US4195523 *||Jul 21, 1978||Apr 1, 1980||European Atomic Energy Community (Euratom)||Ultrasonic thermometer|
|1||*||New Sensors for Ultrasound: Measuring Temp. Profiles, Lynnworth and Patch Materials Research and Standards, Aug. 1970, vol. 10, No. 8.|
|Citing Patent||Filing date||Publication date||Applicant||Title|
|US4623264 *||Apr 26, 1985||Nov 18, 1986||Southland Corporation||Temperature sensing using ultrasonic system and movable target|
|US4706259 *||Dec 30, 1985||Nov 10, 1987||Sundstrand Data Control, Inc.||Mounting and isolation system for tuning fork temperature sensor|
|US4762425 *||Oct 15, 1987||Aug 9, 1988||Parthasarathy Shakkottai||System for temperature profile measurement in large furnances and kilns and method therefor|
|US4772131 *||Mar 30, 1987||Sep 20, 1988||Thermosonics, Inc.||Signal processing apparatus for ultrasonic thermometers|
|US4863280 *||May 12, 1988||Sep 5, 1989||Siemens Aktiengesellschaft||Integral temperature measurement in electrical machines, transformers and energy conversion systems|
|US5022014 *||Jun 14, 1989||Jun 4, 1991||Schlumberger Industries Limited||Ultrasonic temperature sensors, and ultrasonic waveguide connectors for use therewith|
|US5044769 *||Jan 9, 1990||Sep 3, 1991||Schlumberger Industries Limited||Temperature sensors|
|US5674009 *||May 3, 1995||Oct 7, 1997||Weed Instrument Company, Inc.||Adjustable length temperature sensor|
|US6296385 *||May 12, 1998||Oct 2, 2001||Mississippi State University||Apparatus and method for high temperature viscosity and temperature measurements|
|US6517240 *||Nov 5, 1999||Feb 11, 2003||Durametrics, Inc.||Ultrasonic thermometer system|
|US8434936 *||Oct 16, 2009||May 7, 2013||Ge Inspection Technologies, Lp||Method for performing ultrasonic testing|
|US8801277 *||Jan 14, 2011||Aug 12, 2014||University Of Utah Research Foundation||Ultrasonic temperature measurement device|
|US8864371 *||Oct 27, 2011||Oct 21, 2014||Heraeus Electro-Nite International N.V.||Wireless lance|
|US9422806||Oct 4, 2013||Aug 23, 2016||Baker Hughes Incorporated||Downhole monitoring using magnetostrictive probe|
|US20110090935 *||Oct 16, 2009||Apr 21, 2011||John Michael Cuffe||Method for performing ultrasonic testing|
|US20110138920 *||Dec 2, 2010||Jun 16, 2011||Sms Meer Gmbh||Contact-free pipe wall thickness measurement device and pipe wall thickness measurement|
|US20120147921 *||Oct 27, 2011||Jun 14, 2012||Heraeus Electro-Nite International N.V.||Wireless lance|
|US20130121373 *||Jan 14, 2011||May 16, 2013||Mikhail Skliar||Ultrasonic temperature measurement device|
|US20150096942 *||Jul 8, 2014||Apr 9, 2015||Baker Hughes Incorporated||Distributive Temperature Monitoring Using Magnetostrictive Probe Technology|
|US20150098487 *||Jul 10, 2014||Apr 9, 2015||Baker Hughes Incorporated||Magnetostrictive Dual Temperature and Position Sensor|
|US20150337646 *||May 20, 2014||Nov 26, 2015||Baker Hughes Incorporated||Magnetostrictive Apparatus and Method for Determining Position of a Tool in a Wellbore|
|CN103154277A *||Oct 26, 2011||Jun 12, 2013||贺利氏电子耐特国际股份公司||Wireless lance|
|DE4031430A1 *||Oct 4, 1990||Jan 23, 1992||Erhard Weiss||Flowing media measurer esp. for fuel and gases - uses temp. or ultrasonic sensor for continuously measuring temp. and/or density of medium in pipeline|
|EP0351050A1 *||Jun 5, 1989||Jan 17, 1990||Schlumberger Industries Limited||Ultrasonic temperature sensors, and ultrasonic waveguide connectors for use therewith|
|EP0465029A2 *||Jun 13, 1991||Jan 8, 1992||Solartron Group Limited||Distributed temperature sensor|
|EP0465029A3 *||Jun 13, 1991||Apr 15, 1992||Schlumberger Industries Limited||Distributed temperature sensor|
|WO2001035064A1 *||Oct 24, 2000||May 17, 2001||Durametrics, Inc.||Ultrasonic thermometer system|
|WO2015051368A1 *||Oct 6, 2014||Apr 9, 2015||Baker Hughes Incorporated||Magnetostrictive dual temperature and position sensor|
|WO2015167612A1 *||Nov 17, 2014||Nov 5, 2015||Baker Hughes Incorporated||Systems and methods for monitoring temperature using a magnetostrictive probe|
|U.S. Classification||374/119, 374/E11.009, 374/117|
|Apr 1, 1983||AS||Assignment|
Owner name: KERLEY, THOMAS M., 11708 SNOWHEIGHTS N.E. ALBUQUER
Free format text: ASSIGNMENT OF 1/2 OF ASSIGNORS INTEREST;ASSIGNOR:VARELA, DAVID W.;REEL/FRAME:004113/0629
Effective date: 19830110
|Feb 4, 1985||AS||Assignment|
Owner name: THERMOSONICS,INC. P.O. BOX 44273,TOCSON ARIZONA 85
Free format text: ASSIGNMENT OF ASSIGNORS INTEREST.;ASSIGNOR:VARELA DAVID W. AND KERLEY THOMAS M.;REEL/FRAME:004356/0960
Effective date: 19850121
|Jan 19, 1988||FPAY||Fee payment|
Year of fee payment: 4
|Dec 11, 1991||FPAY||Fee payment|
Year of fee payment: 8
|Jun 25, 1996||REMI||Maintenance fee reminder mailed|
|Nov 18, 1996||FPAY||Fee payment|
Year of fee payment: 12
|Nov 18, 1996||SULP||Surcharge for late payment|